Detection device

ABSTRACT

A detection device includes: a substrate having a sensor region in which photosensors are arranged in a first direction and a second direction. In the sensor region, the substrate includes: read control scan lines extending in the first direction and configured to transmit read control signals; and output signal lines extending in the second direction. The photosensors includes: dummy elements comprising first photodiodes and arranged along a contour of the sensor region; and detection elements comprising second photodiodes and arranged on an inner side of a dummy region in which the dummy elements are arranged. The dummy elements are coupled to neither the read control scan lines nor the output signal lines. The detection elements are coupled to the read control scan lines and the output signal lines and are configured to, after receiving the read control signals, output signals generated by the first photodiodes to the output signal lines.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority from Japanese Application No.2020-009441, filed on Jan. 23, 2020, the contents of which areincorporated by reference herein in its entirety.

BACKGROUND 1. Technical Field

The present disclosure relates to a detection device.

2. Description of the Related Art

A liquid crystal display device of Japanese Patent Application Laid-openPublication No. 2010-277378 includes a plurality of photosensors. Thephotosensors each include a photodiode. Light emitted from thephotodiode is converted into a signal (electrical charge). Thephotosensors are typically arranged in a matrix having a row-columnconfiguration. The photosensors arranged in a matrix are used indetection devices, for example, as biometric sensors, such asfingerprint sensors and vein sensors, that detect biologicalinformation.

The photodiode has parasitic capacitance. The photodiode is alsoaffected by the parasitic capacitance of photodiodes adjacent thereto.Photodiodes arranged around a photodiode located in a central portion ofthe photosensors arranged in a matrix are large in number, and thus thephotodiode located in the central portion is affected by a large amountof parasitic capacitance. However, photodiodes arranged around aphotodiode located at an end portion of the photosensors arranged in amatrix are small in number. Therefore, the affected amount of theparasitic capacitance differs between the photodiode located in thecentral portion and the photodiode located at the end portion.

For the foregoing reasons, there is a need for a detection devicecapable of equalizing the affected amount of the parasitic capacitanceof each of the photodiodes.

SUMMARY

According to an aspect, a detection device includes: a substrate havinga sensor region; and a plurality of photosensors arranged in a firstdirection and a second direction orthogonal to the first direction inthe sensor region. The substrate includes: a plurality of read controlscan lines extending in the first direction in the sensor region andconfigured to transmit read control signals; and a plurality of outputsignal lines extending in the second direction in the sensor region. Thephotosensors includes: a plurality of dummy elements comprising firstphotodiodes and arranged along a contour of the sensor region; and aplurality of detection elements comprising second photodiodes andarranged on an inner side of a frame-like dummy region in which thedummy elements are arranged. The dummy elements are coupled to neitherthe read control scan lines nor the output signal lines. The detectionelements are coupled to the read control scan lines and the outputsignal lines and are configured to, after receiving the read controlsignals, output signals generated by the first photodiodes to the outputsignal lines.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a sectional view illustrating a schematic sectionalconfiguration of a detection apparatus having an illumination device,the detection apparatus including a detection device according to anembodiment of the present disclosure;

FIG. 1B is a sectional view illustrating a schematic sectionalconfiguration of the detection apparatus having an illumination device,the detection apparatus including the detection device according to afirst modification of the embodiment;

FIG. 1C is a sectional view illustrating a schematic sectionalconfiguration of the detection apparatus having an illumination device,the detection apparatus including the detection device according to asecond modification of the embodiment;

FIG. 1D is a sectional view illustrating a schematic sectionalconfiguration of the detection apparatus having an illumination device,the detection apparatus including the detection device according to athird modification of the embodiment;

FIG. 2 is a plan view illustrating the detection device according to theembodiment;

FIG. 3 is a plan view obtained by enlarging a portion of a substrate ofthe embodiment;

FIG. 4 is a block diagram illustrating a configuration example of thedetection device according to the embodiment;

FIG. 5 is a circuit diagram illustrating a detection element;

FIG. 6 is a circuit diagram illustrating a dummy element;

FIG. 7 is a plan view illustrating the detection element;

FIG. 8 is a plan view illustrating the dummy element;

FIG. 9 is a sectional view of the detection element, and is, in detail,a IX-IX′ sectional view of FIG. 7; and

FIG. 10 is a sectional view of the dummy element, and is, in detail, aX-X′ sectional view of FIG. 8.

DETAILED DESCRIPTION

The following describes a mode (embodiment) for carrying out the presentinvention in detail with reference to the drawings. The presentdisclosure is not limited to the description of the embodiment givenbelow. Components described below include those easily conceivable bythose skilled in the art or those substantially identical thereto. Inaddition, the components described below can be combined as appropriate.What is disclosed herein is merely an example, and the presentdisclosure naturally encompasses appropriate modifications easilyconceivable by those skilled in the art while maintaining the gist ofthe invention. To further clarify the description, widths, thicknesses,shapes, and the like of various parts may be schematically illustratedin the drawings as compared with actual aspects thereof. However, theyare merely examples, and interpretation of the present disclosure is notlimited thereto. The same component as that described with reference toan already mentioned drawing is denoted by the same reference numeralthrough the description and the drawings, and detailed descriptionthereof may not be repeated where appropriate.

In the present specification and claims, in expressing an aspect ofdisposing another structure on or above a certain structure, a case ofsimply expressing “on” includes both a case of disposing the otherstructure immediately on the certain structure so as to contact thecertain structure and a case of disposing the other structure above thecertain structure with still another structure interposed therebetween,unless otherwise specified.

Embodiment

FIG. 1A is a sectional view illustrating a schematic sectionalconfiguration of a detection apparatus having an illumination device,the detection apparatus including a detection device according to anembodiment of the present disclosure. FIG. 1B is a sectional viewillustrating a schematic sectional configuration of the detectionapparatus having an illumination device, the detection apparatusincluding the detection device according to a first modification of theembodiment. FIG. 1C is a sectional view illustrating a schematicsectional configuration of the detection apparatus having anillumination device, the detection apparatus including the detectiondevice according to a second modification of the embodiment. FIG. 1D isa sectional view illustrating a schematic sectional configuration of thedetection apparatus having an illumination device, the detectionapparatus including the detection device according to a thirdmodification of the embodiment.

As illustrated in FIG. 1A, a detection apparatus 120 having anillumination device includes a detection device 1 and an illuminationdevice 121. The detection device 1 includes a sensor substrate 5, anadhesive layer 125, and a cover member 122. That is, the sensorsubstrate 5, the adhesive layer 125, and the cover member 122 arestacked in the order as listed, in a direction orthogonal to a surfaceof the sensor substrate 5. The cover member 122 of the detection device1 can be replaced with the illumination device 121, as will be describedlater.

As illustrated in FIG. 1A, the illumination device 121 may be, forexample, what is called a side light-type front light that uses thecover member 122 as a light guide plate provided at a locationcorresponding to a sensor region AA of the detection device 1, and thatincludes a plurality of light sources 123 arranged side by side at oneend or both ends of the cover member 122. That is, the cover member 122has a light-emitting surface 121 a for emitting light, and serves as onecomponent of the illumination device 121. The illumination device 121emits light L1 from the light-emitting surface 121 a of the cover member122 toward a finger Fg serving as a detection target. For example,light-emitting diodes (LEDs), which emit light in a predetermined color,are used as the light sources.

As illustrated in FIG. 1B, the illumination device 121 may include lightsources (such as LEDs) provided immediately below the sensor region AAof the detection device 1, and the illumination device 121 including thelight sources serves also as the cover member 122.

The illumination device 121 is not limited to the example of FIG. 1B. Asillustrated in FIG. 1C, the illumination device 121 may be provided on alateral side of or above the cover member 122, and may emit the light L1to the finger Fg from the lateral side of or above the finger Fg.

Furthermore, as illustrated in FIG. 1D, the illumination device 121 maybe what is called a direct-type backlight that includes light sources(such as LEDs) provided in the sensor region AA of the detection device1.

The light L1 emitted from the illumination device 121 is reflected aslight L2 by the finger Fg serving as the detection target. The detectiondevice 1 detects the light L2 reflected by the finger Fg to detectridges and varies (such as a fingerprint) on the surface of the fingerFg. The detection device 1 may further detect the light L2 reflectedinside the finger Fg to detect information on a living body in additionto detecting the fingerprint. Examples of the information on the livingbody include an image of a blood vessel, such as a vein, pulsation, anda pulse wave. The color of the light L1 from the illumination device 121may be varied depending on the detection target.

The cover member 122 is a member for protecting the sensor substrate 5and covers the sensor substrate 5. The illumination device 121 may havea structure to double as the cover member 122 as described above. In thestructures illustrated in FIGS. 1C and 1D in which the cover member 122is separate from the illumination device 121, the cover member 122 is,for example, a glass substrate. The cover member 122 is not limited tothe glass substrate and may be, for example, a resin substrate. Thecover member 122 need not be provided. In this case, the surface of thesensor substrate 5 is provided with a protective layer of, for example,an insulating film, and the finger Fg contacts the protective layer ofthe detection device 1.

As illustrated in FIG. 1B, the detection apparatus 120 having anillumination device may be provided with a display panel instead of theillumination device 121. The display panel may be, for example, anorganic electroluminescent (EL) diode (organic light-emitting diode(OLED)) panel or an inorganic EL display (micro-LED or mini-LED) panel.Alternatively, the display panel may be a liquid crystal display (LCD)panel using liquid crystal elements as display elements or anelectrophoretic display (EPD) panel using electrophoretic elements asdisplay elements. Also in this case, the fingerprint of the finger Fgand the information on the living body can be detected based on thelight L2 resulting from the reflection of the display light (light L1),which has been emitted from the display panel, by the finger Fg.

FIG. 2 is a plan view illustrating the detection device according to theembodiment. A first direction Dx illustrated in FIG. 2 and later figuresis one direction in a plane parallel to a substrate 21 (sensor regionAA). A second direction Dy is another direction in the plane parallel tothe substrate 21 (sensor region AA), and is a direction orthogonal tothe first direction Dx. A third direction Dz is a direction orthogonalto the first direction Dx and the second direction Dy, and is adirection normal to the substrate 21.

As illustrated in FIG. 2, the detection device 1 includes an arraysubstrate 2 (substrate 21), a sensor 10, a scan line drive circuit 15, asignal line selection circuit 16, a detection circuit 48, a controlcircuit 102, and a power supply circuit 103.

The substrate 21 is electrically coupled to a control substrate 101through a wiring substrate 110. The wiring substrate 110 is, forexample, a flexible printed circuit board or a rigid circuit board. Thewiring substrate 110 is provided with the detection circuit 48. Thecontrol substrate 101 is provided with the control circuit 102 and thepower supply circuit 103. The control circuit 102 is, for example, afield-programmable gate array (FPGA). The control circuit 102 suppliescontrol signals to the sensor 10, the scan line drive circuit 15, andthe signal line selection circuit 16 to control operations of the sensor10. The power supply circuit 103 supplies voltage signals including, forexample, a power supply potential VDD and a reference potential VCOM(refer to FIG. 5) to the sensor 10, the scan line drive circuit 15, andthe signal line selection circuit 16. Although the present embodimentexemplifies the case of disposing the detection circuit 48 on the wiringsubstrate 110, the present disclosure is not limited to this case. Thedetection circuit 48 may be disposed on the substrate 21.

The substrate 21 has the sensor region AA and a peripheral region GA.The sensor region AA and the peripheral region GA extend in a planardirection parallel to the substrate 21. Elements (a detection element 3Aand a dummy element 3B) of the sensor 10 are provided in the sensorregion AA. The peripheral region GA is a region outside the sensorregion AA, and is a region not provided with the elements (the detectionelement 3A and the dummy element 3B). That is, the peripheral region GAis a region between the outer circumference of the sensor region AA andouter edges of the substrate 21. The scan line drive circuit 15 and thesignal line selection circuit 16 are provided in the peripheral regionGA. The scan line drive circuit 15 is provided in a region extendingalong the second direction Dy in the peripheral region GA. The signalline selection circuit 16 is provided in a region extending along thefirst direction Dx in the peripheral region GA and is provided betweenthe sensor 10 and the detection circuit 48.

The sensor region AA includes a detection region AA1 located in acentral portion of the sensor region AA and a frame-like dummy regionAA2 along the contour of the sensor region AA. The detection region AA1has a rectangular shape. The dummy region AA2 has a rectangular frameshape and surrounds the detection region AA1. The detection region AA1is provided with the detection element 3A that detects, for example, thefingerprint and the information on the living body. The dummy region AA2is provided with the dummy element 3B that does not detect, for example,the fingerprint.

FIG. 3 is a plan view obtained by enlarging a portion of the substrateof the embodiment. As illustrated in FIG. 3, the substrate 21 includestwo kinds of scan lines (a read control scan line GLrd and a resetcontrol scan line GLrst) and three kinds of signal lines (an outputsignal line SL, a power supply signal line SLsf, and a reset signal lineSLrst). The read control scan line GLrd and the reset control scan lineGLrst are led out from the scan line drive circuit 15 into the sensorregion AA. The read control scan line GLrd and the reset control scanline GLrst extend in the first direction Dx and are arranged in thesecond direction Dy in the sensor region AA. The output signal line SL,the power supply signal line SLsf, and the reset signal line SLrst areled out from the signal line selection circuit 16 into the sensor regionAA. The output signal line SL, the power supply signal line SLsf, andthe reset signal line SLrst extend in the second direction Dy and arearranged in the first direction Dx in the sensor region AA.

A region surrounded by two scan lines and two signal lines correspondsto one unit region. In the present embodiment, a region surrounded bytwo output signal lines SL separately arranged in the first direction Dxand two reset control scan lines GLrst separately arranged in the seconddirection Dy corresponds to one unit region. The detection element 3A orthe dummy element 3B of the sensor 10 is disposed one in each unitregion. That is, an arrangement pitch Px in the first direction Dx ofthe one unit region is defined by an arrangement pitch of the outputsignal lines SL, and an arrangement pitch Py in the second direction Dyof the one unit region is defined by an arrangement pitch of the resetcontrol scan lines GLrst. The dummy region AA2 of the present embodimentoccupies a width of one unit region from the contour of the sensorregion AA.

The sensor 10 includes a plurality of the detection elements 3A and aplurality of the dummy elements 3B. The dummy elements 3B are providedin the dummy region AA2. In other words, the dummy elements 3B arearranged along the contour of the sensor region AA. The detectionelements 3A are provided in the detection region AA1. That is, thedetection elements 3A are arranged on an inner side of the frame-likedummy region AA2.

Each of the detection element 3A and the dummy element 3B includes aphotoelectric conversion element 30. Each photoelectric conversionelement 30 is a photodiode and outputs an electrical signalcorresponding to light irradiating the photoelectric conversion element30. More specifically, the photoelectric conversion element 30 is apositive-intrinsic-negative (PIN) photodiode. Hereinafter, thephotoelectric conversion element 30 of the detection element 3A iscalled a “photoelectric conversion element 30A”, and the photoelectricconversion element 30 of the dummy element 3B is called a “photoelectricconversion element 30B”. A plurality of the detection elements 3A and aplurality of the dummy elements 3B may be collectively called aplurality of photosensors. The photoelectric conversion element 30B ofthe dummy element 3B may be called a first photodiode. The photoelectricconversion element 30A of the detection element 3A may be called asecond photodiode.

The photoelectric conversion element 30A of the detection element 3Aoperates in accordance with a gate drive signal (a reset control signalRST or a read control signal RD) supplied from the scan line drivecircuit 15. Each photoelectric conversion element 30A outputs anelectrical signal corresponding to light irradiating the photoelectricconversion element 30A as a detection signal Vdet to the signal lineselection circuit 16. The detection device 1 detects the information onthe living body based on the detection signals Vdet received from thephotoelectric conversion elements 30. The photoelectric conversionelement 30B of the dummy element 3B operates in accordance with the gatedrive signal (reset control signal RST) supplied from the scan linedrive circuit 15. The photoelectric conversion element 30B generates anelectrical signal corresponding to the irradiating light but does notoutput the electrical signal to the signal line selection circuit 16because the photoelectric conversion element 30B is not coupled to thesignal line selection circuit 16.

FIG. 4 is a block diagram illustrating a configuration example of thedetection device according to the embodiment. As illustrated in FIG. 4,the detection device 1 further includes a detection control circuit 11and a detector 40. One, some, or all functions of the detection controlcircuit 11 are included in the control circuit 102. One, some, or allfunctions of the detector 40 other than those of the detection circuit48 are also included in the control circuit 102.

The detection control circuit 11 supplies control signals to the scanline drive circuit 15, the signal line selection circuit 16, and thedetector 40 to control operations of these components. The detectioncontrol circuit 11 supplies various control signals including, forexample, a start signal STV and a clock signal CK to the scan line drivecircuit 15. The detection control circuit 11 also supplies variouscontrol signals including, for example, a selection signal ASW to thesignal line selection circuit 16.

The scan line drive circuit 15 drives a plurality of scan lines (theread control scan lines GLrd and the reset control scan lines GLrst(refer to FIG. 3)) based on the various control signals. The scan linedrive circuit 15 sequentially or simultaneously selects the scan linesand supplies the gate drive signal (for example, the reset controlsignal RST or the read control signal RD) to the selected scan lines.Through this operation, the scan line drive circuit 15 selects thephotoelectric conversion elements 30 coupled to the scan lines.

The signal line selection circuit 16 is a switching circuit thatsequentially or simultaneously selects the output signal lines SL (referto FIG. 3). The signal line selection circuit 16 is, for example, amultiplexer. The signal line selection circuit 16 couples the selectedoutput signal lines SL to the detection circuit 48 based on theselection signal ASW supplied from the detection control circuit 11.Through this operation, the signal line selection circuit 16 outputs thedetection signal Vdet of the photoelectric conversion element 30 to thedetector 40.

The detector 40 includes the detection circuit 48, a signal processingcircuit 44, a coordinate extraction circuit 45, a storage circuit 46,and a detection timing control circuit 47. The detection timing controlcircuit 47 performs control to cause the detection circuit 48, thesignal processing circuit 44, and the coordinate extraction circuit 45to operate in synchronization with one another based on a control signalsupplied from the detection control circuit 11.

The detection circuit 48 is, for example, an analog front end (AFE)circuit. The detection circuit 48 is a signal processing circuit havingfunctions of at least a detection signal amplifying circuit 42 and ananalog-to-digital (A/D) conversion circuit 43. The detection signalamplifying circuit 42 is a circuit that amplifies the detection signalVdet, and is, for example, an integration circuit. The A/D conversioncircuit 43 converts an analog signal output from the detection signalamplifying circuit 42 into a digital signal.

The signal processing circuit 44 is a logic circuit that detects apredetermined physical quantity received by the sensor 10 based onoutput signals of the detection circuit 48. The signal processingcircuit 44 can detect ridges and varies on a surface of the finger Fg ora palm based on the signals from the detection circuit 48 when thefinger Fg is in contact with or in proximity to a detection surface. Thesignal processing circuit 44 may detect the information on the livingbody based on the signals from the detection circuit 48. Examples of theinformation on the living body include an image of a blood vessel of thefinger Fg or the palm, a pulse wave, pulsation, and blood oxygensaturation.

The storage circuit 46 temporarily stores signals calculated by thesignal processing circuit 44. The storage circuit 46 may be, forexample, a random-access memory (RAM) or a register circuit.

The coordinate extraction circuit 45 is a logic circuit that obtainsdetected coordinates of the ridges and varies on the surface of thefinger Fg or the like when the contact or proximity of the finger Fg isdetected by the signal processing circuit 44. The coordinate extractioncircuit 45 is the logic circuit that also obtains detected coordinatesof blood vessels of the finger Fg or the palm. The coordinate extractioncircuit 45 combines the detection signals Vdet output from therespective detection elements 3A of the sensor 10 to generatetwo-dimensional information representing a shape of the ridges andvaries on the surface of the finger Fg or the like. The coordinateextraction circuit 45 may output the detection signals Vdet as sensoroutputs Vo instead of calculating the detected coordinates.

The following describes a circuit configuration example of the detectiondevice 1. FIG. 5 is a circuit diagram illustrating the detectionelement. As illustrated in FIG. 5, the detection element 3A includes thephotoelectric conversion element 30A, a reset transistor Mrst, a readtransistor Mrd, and a source follower transistor Msf. Each of the resettransistor Mrst, the read transistor Mrd, and the source followertransistor Msf is made up of an n-type thin film transistor (TFT).However, each of the transistors is not limited thereto and may be madeup of a p-type TFT.

The reference potential VCOM is applied to an anode of the photoelectricconversion element 30A. A cathode of the photoelectric conversionelement 30A is coupled to a node N1. The node N1 is coupled to acapacitive element Cs, one of the source and the drain of the resettransistor Mrst, and the gate of the source follower transistor Msf. Inaddition, the node N1 has parasitic capacitance Cp. When light entersthe photoelectric conversion element 30A, a signal (electrical charge)output from the photoelectric conversion element 30A is stored in thecapacitive element Cs.

The gates of the reset transistor Mrst are coupled to the reset controlscan line GLrst. One of the source and the drain of the reset transistorMrst is coupled to the reset signal line SLrst and is supplied with areset potential Vrst. When the reset transistor Mrst is turned on (intoa conduction state) in response to the reset control signal RST, thepotential of the node N1 is reset to the reset potential Vrst. Thereference potential VCOM is lower than the reset potential Vrst, and thephotoelectric conversion element 30A is driven in a reverse bias state.

The source follower transistor Msf is coupled between a terminalsupplied with the power supply potential VDD and the read transistor Mrd(node N2). The gate of the source follower transistor Msf is coupled tothe node N1. The gate of the source follower transistor Msf is suppliedwith the signal (electrical charge) generated by the photoelectricconversion element 30A. This operation causes the source followertransistor Msf to output a signal voltage corresponding to the signal(electrical charge) generated by the photoelectric conversion element30A to the read transistor Mrd.

The read transistor Mrd is coupled between the source of the sourcefollower transistor Msf (node N2) and the output signal line SL (nodeN3). The gates of the read transistor Mrd are coupled to the readcontrol scan line GLrd. When the read transistor Mrd is turned on inresponse to the read control signal RD, the signal output from thesource follower transistor Msf, that is, the signal voltagecorresponding to the signal (electrical charge) generated by thephotoelectric conversion element 30A is output as the detection signalVdet to the output signal line SL.

FIG. 6 is a circuit diagram illustrating the dummy element. Asillustrated in FIG. 6, the dummy element 3B includes the photoelectricconversion element 30B and the reset transistor Mrst. The referencepotential VCOM is applied to the anode of the photoelectric conversionelement 30B. The cathode of the photoelectric conversion element 30 iscoupled to the node N1. The node N1 is coupled to the capacitive elementCs and one of the source and the drain of the reset transistor Mrst. Inaddition, the node N1 has parasitic capacitance Cp. When thephotoelectric conversion element 30 is irradiated with light, the signal(electrical charge) output from the photoelectric conversion element 30is stored in the capacitive element Cs.

The gates of the reset transistor Mrst are coupled to the reset controlscan line GLrst. The other one of the source and the drain of the resettransistor Mrst is coupled to the reset signal line SLrst and issupplied with the reset potential Vrst. When the reset transistor Mrstis turned on (into the conduction state) in response to the resetcontrol signal RST, the potential of the node N1 is reset to the resetpotential Vrst. The reference potential VCOM is lower than the resetpotential Vrst, and the photoelectric conversion element 30 is driven inthe reverse bias state.

The dummy element 3B includes neither the read transistor Mrd nor thesource follower transistor Msf. Hence, the dummy element 3B is coupledto neither the read control scan line GLrd coupled to the readtransistor Mrd nor the output signal line SL coupled to the sourcefollower transistor Msf. As a result, the signal (electrical charge)generated by the photoelectric conversion element 30B is not output asthe detection signal Vdet to the output signal line SL.

The reset transistor Mrst and the read transistor Mrd illustrated inFIG. 5 and the reset transistor Mrst illustrated in FIG. 6 each havewhat is called a double-gate structure configured by coupling twotransistors in series. However, the structures of those transistors arenot limited thereto; the reset transistor Mrst and the read transistorMrd may have a single-gate structure or a structure configured bycoupling three or more transistors in series.

The following describes planar configurations of the detection element3A and the dummy element 3B. FIG. 7 is a plan view illustrating thedetection element. FIG. 8 is a plan view illustrating the dummy element.The detection element 3A and the dummy element 3B include thephotoelectric conversion elements 30A and 30B and the reset transistorMrst as a common configuration. Therefore, the common parts (thephotoelectric conversion elements 30A and 30B and the reset transistorMrst) will be collectively described with reference to FIGS. 7 and 8.

As illustrated in FIGS. 7 and 8, the photoelectric conversion element30A of the detection element 3A and the photoelectric conversion element30B of the dummy element 3B are each provided in a region surrounded bytwo of the reset control scan lines GLrst adjacent in the seconddirection Dy and two of the output signal lines SL adjacent in the firstdirection Dx. Consequently, the photosensors (the photoelectricconversion elements 30A and the photoelectric conversion elements 30B)are regularly arranged in the first direction Dx and the seconddirection Dy.

As illustrated in FIGS. 7 and 8, the reset transistors Mrst of thedetection element 3A and the dummy element 3B respectively includesemiconductor layers 61A and 61B, source electrodes 62A and 62B, drainelectrodes 63A and 63B, and gate electrodes 64A and 64B. One end of eachof the semiconductor layers 61A and 61B is coupled to the reset signalline SLrst. The other end of each of the semiconductor layers 61A and61B is coupled to coupling wiring SLcn. Portions of the reset signallines SLrst coupled to the semiconductor layers 61A and 61B serve as thesource electrodes 62A and 62B, respectively. Portions of the couplingwiring SLcn coupled to the semiconductor layers 61A and 61B serve as thedrain electrodes 63A and 63B, respectively. The reset control scan lineGLrst is provided with two branches branching in the second directionDy, and each of the semiconductor layers 61A and 61B intersects the twobranches of the corresponding reset control scan line GLrst. Channelregions are formed at portions of each of the semiconductor layers 61Aand 61B overlapping the two branches of the corresponding reset controlscan line GLrst. Portions of the two branches of the reset control scanline GLrst overlapping the semiconductor layer 61A serve as the gateelectrodes 64A. Portions of the two branches of the reset control scanline GLrst overlapping the semiconductor layer 61B serve as the gateelectrodes 64B.

As illustrated in FIG. 7, the source follower transistor Msf of thedetection element 3A includes a semiconductor layer 65, a sourceelectrode 67, and a gate electrode 68. One end of the semiconductorlayer 65 is coupled to the power supply signal line SLsf through acoupling portion SLsfa. The other end of the semiconductor layer 65 iscoupled to the read transistor Mrd. A portion of the coupling portionSLsfa coupled to the semiconductor layer 65 serves as the sourceelectrode 67.

One end of the gate electrode 68 of the detection element 3A is coupledto the coupling wiring SLcn through a contact hole. The semiconductorlayer 65 intersects the gate electrode 68. That is, the reset transistorMrst is electrically coupled to the gate of the source followertransistor Msf through the coupling wiring SLcn.

The cathode (n-type semiconductor layer 33A) of the photoelectricconversion element 30A of the detection element 3A is coupled to thecoupling wiring SLcn through a contact hole H2. This configurationelectrically couples the cathode (n-type semiconductor layer 33) of thephotoelectric conversion element 30A to the reset transistor Mrst andthe source follower transistor Msf through the coupling wiring SLcn.

The read transistor Mrd includes a semiconductor layer 71, a drainelectrode 72, and gate electrodes 74. One end of the semiconductor layer71 is coupled to the semiconductor layer 65 of the source followertransistor Msf. In the present embodiment, the semiconductor layers 65and 71 are formed of a common semiconductor layer. The other end of thesemiconductor layer 71 is coupled to the output signal line SL through acoupling portion SLa. In other words, a portion of the coupling portionSLa coupled to the semiconductor layer 71 serves as the drain electrode72. The read control scan line GLrd is coupled to a branch that isadjacent to the read control scan line GLrd in the second direction Dyand extends in the first direction Dx. The semiconductor layer 71intersects the read control scan line GLrd and the branch. Portions ofthe read control scan line GLrd and the branch overlapping thesemiconductor layer 71 serve as the gate electrodes 74. With theabove-described configuration, the source follower transistor Msf andthe read transistor Mrd are coupled to the output signal line SL.

The planar configurations of the photoelectric conversion elements 30Aand 30B and the transistors illustrated in FIGS. 7 and 8 are merelyexamples, and can be changed as appropriate. For example, the presentdisclosure is not limited to the configuration in which the transistorsare arranged in the second direction Dy. One or some of the transistorsmay each be provided at a different location, for example, by beingarranged adjacent to another transistor in the first direction Dx. Thearrangement of the signal lines and the scan lines may also beappropriately changed depending on the arrangement of the transistors.

The following describes sectional configurations of the detectionelement 3A and the dummy element 3B. FIG. 9 is a sectional view of thedetection element and is, in detail, an IX-IX′sectional view of FIG. 7.FIG. 10 is a sectional view of the dummy element and is, in detail, anX-X′ sectional view of FIG. 8. The detection element 3A and the dummyelement 3B are formed on the same substrate 21 and have substantiallythe same sectional configuration. Therefore, the detection element 3Aand the dummy element 3B will be collectively described with referenceto FIGS. 9 and 10. While FIG. 9 illustrates a sectional configuration ofthe reset transistor Mrst among the three transistors included in thedetection element 3A, each of the source follower transistor Msf and theread transistor Mrd also has a sectional configuration similar to thatof the reset transistor Mrst.

As illustrated in FIGS. 9 and 10, the substrate 21 is an insulatingsubstrate. For example, a glass substrate of, for example, quartz oralkali-free glass is used as the substrate 21. The substrate 21 has afirst principal surface 51 and a second principal surface S2 on theopposite side of the first principal surface 51. The first principalsurface 51 of the substrate 21 is provided with various transistorsincluding the reset transistor Mrst, various types of wiring (the scanlines and the signal lines), and insulating films to form the arraysubstrate 2. The photoelectric conversion elements 30A and 30B arearranged on the array substrate 2, that is, on the first principalsurface 51 side of the substrate 21.

An undercoat film 22 is provided on the first principal surface 51 ofthe substrate 21. The undercoat film 22, insulating films 23, 24, and25, and insulating films 27 and 28 are inorganic insulating films, andare formed of, for example, a silicon oxide (SiO₂) or a silicon nitride(SiN).

The semiconductor layers 61A and 61B are provided on the undercoat film22. For example, polysilicon is used as the semiconductor layers 61A and61B. The semiconductor layers 61A and 61B are, however, not limitedthereto, and may be formed of, for example, a microcrystalline oxidesemiconductor, an amorphous oxide semiconductor, or low-temperaturepolycrystalline silicon (LTPS).

The insulating film 23 is provided on the undercoat film 22 so as tocover the semiconductor layers 61A and 61B. The gate electrodes 64A and64B are provided on the insulating film 23. The gate electrode 68 of thesource follower transistor Msf is also provided in the same layer asthat of the gate electrodes 64A and 64B on the insulating film 23. Thereset control scan line GLrst and the read control scan line GLrd arealso provided in the same layer as that of the gate electrodes 64A and64B. The insulating film 24 is provided on the insulating film 23 so asto cover the gate electrodes 64A and 64B. In the detection region AA1,the insulating film 24 covers the source follower transistor Msf asillustrated in FIG. 9.

As illustrated in FIGS. 9 and 10, each of the reset transistors Mrsthave a top-gate structure in which the gate electrode 64A or 64B isprovided on the upper side of the semiconductor layer 61A or 61B.However, in the detection device 1 of the present disclosure, the resettransistor Mrst may have a bottom-gate structure in which the gateelectrode 64A or 64B is provided on the lower side of the semiconductorlayer 61A or 61B, or a dual-gate structure in which the gate electrode64A or 64B is provided on the upper side and lower side of thesemiconductor layers 61A and 61B.

The insulating films 24 and 25 are provided on the insulating film 23 soas to cover the gate electrodes 64A and 64B. The source electrodes 62Aand 62B and the drain electrodes 63A and 63B are provided on theinsulating film 25. The source electrodes 62A and 62B and the drainelectrodes 63A and 63B are respectively coupled to the semiconductorlayers 61A and 61B through a contact hole penetrating the insulatingfilms 23, 24, and 25. The source electrodes 62A and 62B and the drainelectrodes 63A and 63B are formed of, for example, a multilayered filmTi—Al—Ti or Ti—Al having a multilayered structure of titanium andaluminum.

The various signal lines (the output signal line SL, the power supplysignal line SLsf, and the reset signal line SLrst) and the couplingwiring SLcn are provided in the same layer as that of the sourceelectrodes 62A and 62B and the drain electrodes 63A and 63B. Asillustrated in FIG. 9, the coupling wiring SLcn of the detection element3A is coupled to the gate electrode 68 of the source follower transistorMsf through a contact hole penetrating the insulating films 24 and 25.

As illustrated in FIGS. 9 and 10, an insulating film 26 is provided onthe insulating film 25 so as to cover the various transistors including,for example, the reset transistor Mrst. The insulating film 26 is formedof an organic material such as a photosensitive acrylic resin. Theinsulating film 26 is thicker than the insulating film 25. Theinsulating film 26 has a better step covering property than that ofinorganic insulating materials, and can planarize steps formed by thevarious transistors and the various types of wiring.

The following describes sectional configurations of the photoelectricconversion elements 30A and 30B. The photoelectric conversion elements30A and 30B are provided on the insulating film 26. Specifically, lowerconductive layers 35A and 35B are provided on the insulating film 26 andare electrically coupled to the coupling wiring SLcn through the contactholes H2. The photoelectric conversion elements 30A and 30B are coupledto the lower conductive layers 35A and 35B. In a plan view, the lowerconductive layers 35A and 35B have larger areas than those of thephotoelectric conversion elements 30A and 30B. The lower conductivelayers 35A and 35B can employ, for example, a multilayered structure oftitanium (Ti) and titanium nitride (TiN). Since the lower conductivelayers 35A and 35B are provided between the substrate 21 and thephotoelectric conversion elements 30A and 30B, the lower conductivelayers 35A and 35B serve as light blocking layers, and can restrainlight from entering the photoelectric conversion elements 30A and 30Bfrom the second principal surface S2 side of the substrate 21.

The photoelectric conversion elements 30A and 30B are configured so asto include semiconductor layers having a photovoltaic effect.Specifically, the semiconductor layers of the photoelectric conversionelements 30A and 30B include i-type semiconductor layers 31A and 31B,p-type semiconductor layers 32A and 32B, and n-type semiconductor layers33A and 33B. The i-type semiconductor layers 31A and 31B, the p-typesemiconductor layers 32A and 32B, and the n-type semiconductor layers33A and 33B are formed of, for example, amorphous silicon (a-Si). Thematerial of the semiconductor layers is not limited thereto, and may be,for example, polysilicon or microcrystalline silicon.

The a-Si of each of the p-type semiconductor layers 32A and 32B is dopedwith impurities to form a p+ region. The a-Si of each of the n-typesemiconductor layers 33A and 33B is doped with impurities to form an n+region. The i-type semiconductor layers 31A and 31B are, for example,non-doped intrinsic semiconductors and have lower conductivity than thatof the p-type semiconductor layers 32A and 32B and the n-typesemiconductor layers 33A and 33B.

The i-type semiconductor layers 31A and 31B are provided between then-type semiconductor layers 33A and 33B and the p-type semiconductorlayers 32A and 32B in a direction orthogonal to a surface of thesubstrate 21 (in the third direction Dz). In the present embodiment, then-type semiconductor layers 33A and 33B, the i-type semiconductor layers31A and 31B, and the p-type semiconductor layers 32A and 32B are stackedon the lower conductive layers 35A and 35B in the order as listed.

With this configuration, the n-type semiconductor layer 33A of thephotoelectric conversion element 30A of the detection element 3A iselectrically coupled to the reset transistor Mrst and the sourcefollower transistor Msf through the lower conductive layer 35A and thecoupling wiring SLcn. By contrast, the n-type semiconductor layer 33B ofthe photoelectric conversion element 30B of the dummy element 3B iselectrically coupled to the reset transistor Mrst through the lowerconductive layer 35B and the coupling wiring SLcn.

Upper electrodes 34A and 34B are provided on the p-type semiconductorlayers 32A and 32B. The upper electrodes 34A and 34B are formed of, forexample, a light-transmitting conductive material such as indium tinoxide (ITO). The insulating film 27 is provided on the insulating film26 so as to cover the photoelectric conversion elements 30A and 30B andthe upper electrodes 34A and 34B. The insulating film 27 is providedwith contact holes H1 in regions overlapping the upper electrodes 34Aand 34B.

Coupling wiring 36A and coupling wiring 36B are provided on theinsulating film 27, and are electrically coupled to the upper electrodes34A and 34B through the contact holes H1. The p-type semiconductorlayers 32A and 32B are supplied with the reference potential VCOM (referto FIGS. 5 and 6) through the coupling wiring 36A and 36B.

The insulating film 28 is provided on the insulating film 27 so as tocover the upper electrodes 34A and 34B and the coupling wiring 36A and36B. The insulating film 28 is provided as a protection layer forrestraining water from entering the photoelectric conversion elements30A and 30B. In addition, an insulating film 29 is provided on theinsulating film 28. The insulating film 29 is a hard coat film formed ofan organic material. The insulating film 29 planarizes steps on asurface of the insulating film 28 formed by the photoelectric conversionelements 30A and 30B and the coupling wiring 36A and 36B.

The cover member 122 is provided so as to face the insulating film 29.That is, the cover member 122 is provided so as to cover the varioustransistors and the photoelectric conversion elements 30A and 30B. Theadhesive layer 125 bonds the insulating film 29 to the cover member 122.The adhesive layer 125 is, for example, a light-transmitting opticalclear adhesive (OCA) sheet.

The following describes operational advantages of the detectionapparatus 120 having an illumination device according to the embodiment.As illustrated in FIG. 1A, when the fingerprint is detected, the lightL1 emitted from the illumination device 121 hits the finger Fg (refer toFIG. 1A). The light L2 that has hit and reflected from the finger Fgenters the sensor region AA. The light L2 enters the photoelectricconversion elements 30A of the detection elements 3A provided in thedetection region AA1 and the photoelectric conversion elements 30B ofthe dummy elements 3B provided in the dummy region AA2. Thephotoelectric conversion elements 30A and 30B generate the signals(electrical charges) based on the incident light. This generates theparasitic capacitance in the photoelectric conversion elements 30A and30B.

A photoelectric conversion element 30A that is disposed in the detectionregion AA1 and away inward from the contour of the detection region AA1by one pitch is adjacent to other photoelectric conversion elements 30Ain the first direction Dx and the second direction Dy. Consequently, thephotoelectric conversion element 30A is affected by the parasiticcapacitance generated in four of the photoelectric conversion elements30A adjacent thereto in the first direction Dx and the second directionDy.

By contrast, as illustrated in FIG. 3, a photoelectric conversionelement 30A disposed in the detection region AA1 and alongside of thecontour of the detection region AA1 is adjacent to the photoelectricconversion elements 30A and 30B in the first direction Dx and the seconddirection Dy. Consequently, the photoelectric conversion element 30A isaffected by the parasitic capacitance generated in the photoelectricconversion elements 30A and 30B adjacent thereto in the first directionDx and the second direction Dy.

As a result of the above, the photoelectric conversion elements 30Aarranged in the detection region AA1 are made to have no difference inthe parasitic capacitance affected from the surroundings, and are madeuniform in the parasitic capacitance. As a result, noise added to thesignals (electrical charges) converted by the photoelectric conversionelements 30A is also equalized.

After the fingerprint is detected, the scan line drive circuit 15sequentially selects the read control scan line GLrd. Each of thedetection elements 3A coupled to the selected read control scan lineGLrd transmits the detection signal Vdet through its respective outputsignal line SL to the detector 40. Then, the reset control signal istransmitted through the reset control scan line GLrst to each of thedetection elements 3A and each of the dummy elements 3B. This causes thephotoelectric conversion elements 30A and 30B to be driven in thereverse bias state so as to be in a reset state. As a result, theparasitic capacitance of the photoelectric conversion elements 30A and30B is also reset.

The following describes the design of the detection device 1. The dummyelements 3B are components for surrounding the detection elements 3A ofthe detection region AA1 to affect the parasitic capacitance of thephotoelectric conversion elements 30A arranged alongside of the contourof the detection region AA1. Therefore, the dummy elements 3B need nothave the same size as that of the detection elements 3A. In other words,the dummy elements 3B may be designed to be larger or smaller than thedetection elements 3A. Therefore, the detection region AA1 can bedetermined by arranging the detection elements 3A having a predeterminedsize in the designated sensor region AA, and the remaining area can beused as the dummy region AA2. Consequently, out of the sensor region AA,a space other than the detection region AA1 can be effectively used.With this design, the detection elements 3A do not fill the entiresensor region AA, so that favorable productivity is achieved.

In the dummy region AA2 of the present embodiment, the region in whichthe dummy elements 3B are arranged corresponds to one unit region.However, the detection device of the present disclosure is not limitedthereto. The region may correspond to a plurality of unit regions. Ifthe dummy elements 3B are arranged in twos so as to form a ring shape inthe dummy region AA2, a photoelectric conversion element 30A arranged inthe detection region AA1 and alongside of the contour of the detectionregion AA1 is affected by the parasitic capacitance of two of thephotoelectric conversion elements 30B arranged outside thereof. As aresult, the parasitic capacitance of the photoelectric conversionelement 30A can be closer to the parasitic capacitance by which thephotoelectric conversion elements 30A disposed in a central portion ofthe detection region AA1 are affected.

As described above, the detection device 1 of the embodiment can alsoequalize the noise added to the signals (electrical charges) convertedby the photoelectric conversion elements (photodiode) 30A, and theaccuracy of the detected fingerprint is improved. The dummy elements 3Bare arranged by using the remaining space of the sensor region AA, sothat the detection device 1 is avoided from increasing in size. Inaddition, the parasitic capacitance of the photoelectric conversionelements 30A and 30B is reset after the fingerprint is detected, so thatthe components of the detection device 1 are also less affected.

While the preferred embodiment of the present disclosure has beendescribed above, the present disclosure is not limited to the embodimentdescribed above. The content disclosed in the embodiment is merelyexemplary, and can be variously changed within the scope not departingfrom the gist of the present disclosure. Any modification appropriatelymade within the scope not departing from the gist of the presentdisclosure also naturally belongs to the technical scope of the presentdisclosure.

What is claimed is:
 1. A detection device comprising: a substrate havinga sensor region; and a plurality of photosensors arranged in a firstdirection and a second direction orthogonal to the first direction inthe sensor region, wherein the substrate comprises: a plurality of readcontrol scan lines extending in the first direction in the sensor regionand configured to transmit read control signals; and a plurality ofoutput signal lines extending in the second direction in the sensorregion, the photosensors comprise: a plurality of dummy elementscomprising first photodiodes and arranged along a contour of the sensorregion; and a plurality of detection elements comprising secondphotodiodes and arranged on an inner side of a frame-like dummy regionin which the dummy elements are arranged, the dummy elements are coupledto neither the read control scan lines nor the output signal lines, andthe detection elements are coupled to the read control scan lines andthe output signal lines and are configured to, after receiving the readcontrol signals, output signals generated by the first photodiodes tothe output signal lines.
 2. The detection device according to claim 1,wherein the substrate comprises: reset control scan lines configured totransmit reset control signals; and reset signal lines configured tosupply a reset potential, and each of the detection elements and thedummy elements is coupled to a corresponding one of the reset controlscan lines and a corresponding one of the reset signal lines andconfigured to, after receiving the reset control signal, use the resetpotential to drive the first photodiode or the second photodiode in areverse bias state.
 3. The detection device according to claim 2,wherein anodes of the first photodiodes and anodes of the secondphotodiodes are coupled to a reference potential on the substrate. 4.The detection device according to claim 3, wherein the detectionelements each comprises a reset transistor, a read transistor, and asource follower transistor, the reset signal lines are coupled tosources of the reset transistors, the reset control scan lines arecoupled to gates of the reset transistors, drains of the resettransistors are coupled to gates of the source follower transistors,cathodes of the second photodiodes are coupled to the gates of thesource follower transistors, drains of the source follower transistorsare coupled to sources of the read transistors, the read control scanlines are coupled to gates of the read transistors, and the outputsignal lines are coupled to drains of the read transistors.
 5. Thedetection device according to claim 4, wherein the dummy elements eachcomprises a reset transistor, gates of the reset transistors of thedummy elements are coupled to the reset control scan lines, sources ofthe reset transistors of the dummy elements are coupled to the resetsignal lines, and drains of the reset transistors of the dummy elementsare coupled to cathodes of the first photodiodes.
 6. The detectiondevice according to claim 5, wherein the substrate further comprisespower supply signal lines, the power supply signal lines are coupled tosources of the source follower transistors of the detection elements,and the dummy elements are not coupled to the power supply signal lines.